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CommandStation-EX/DCCEXParser.cpp
2024-02-01 22:05:03 +01:00

1185 lines
37 KiB
C++

/*
* © 2022 Paul M Antoine
* © 2021 Neil McKechnie
* © 2021 Mike S
* © 2021 Herb Morton
* © 2020-2023 Harald Barth
* © 2020-2021 M Steve Todd
* © 2020-2021 Fred Decker
* © 2020-2021 Chris Harlow
* © 2022 Colin Murdoch
* All rights reserved.
*
* This file is part of CommandStation-EX
*
* This is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* It is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with CommandStation. If not, see <https://www.gnu.org/licenses/>.
*/
/*
List of single character OPCODEs in use for reference.
When determining a new OPCODE for a new feature, refer to this list as the source of truth.
Once a new OPCODE is decided upon, update this list.
Character, Usage
/, |EX-R| interactive commands
-, Remove from reminder table
=, |TM| configuration
!, Emergency stop
@, Reserved for future use - LCD messages to JMRI
#, Request number of supported cabs/locos; heartbeat
+, WiFi AT commands
?, Reserved for future use
0, Track power off
1, Track power on
a, DCC accessory control
A,
b, Write CV bit on main
B, Write CV bit
c, Request current command
C,
d,
D, Diagnostic commands
e, Erase EEPROM
E, Store configuration in EEPROM
f, Loco decoder function control (deprecated)
F, Loco decoder function control
g,
G,
h,
H, Turnout state broadcast
i, Reserved for future use - Turntable object broadcast
I, Reserved for future use - Turntable object command and control
j, Throttle responses
J, Throttle queries
k, Reserved for future use - Potentially Railcom
K, Reserved for future use - Potentially Railcom
l, Loco speedbyte/function map broadcast
L,
m,
M, Write DCC packet
n,
N,
o,
O, Output broadcast
p, Broadcast power state
P, Write DCC packet
q, Sensor deactivated
Q, Sensor activated
r, Broadcast address read on programming track
R, Read CVs
s, Display status
S, Sensor configuration
t, Cab/loco update command
T, Turnout configuration/control
u, Reserved for user commands
U, Reserved for user commands
v,
V, Verify CVs
w, Write CV on main
W, Write CV
x,
X, Invalid command
y,
Y, Output broadcast
z,
Z, Output configuration/control
*/
#include "StringFormatter.h"
#include "DCCEXParser.h"
#include "DCC.h"
#include "DCCWaveform.h"
#include "Turnouts.h"
#include "Outputs.h"
#include "Sensors.h"
#include "GITHUB_SHA.h"
#include "version.h"
#include "defines.h"
#include "CommandDistributor.h"
#include "EEStore.h"
#include "DIAG.h"
#include "TrackManager.h"
#include "DCCTimer.h"
#include "EXRAIL2.h"
// This macro can't be created easily as a portable function because the
// flashlist requires a far pointer for high flash access.
#define SENDFLASHLIST(stream,flashList) \
for (int16_t i=0;;i+=sizeof(flashList[0])) { \
int16_t value=GETHIGHFLASHW(flashList,i); \
if (value==INT16_MAX) break; \
StringFormatter::send(stream,F(" %d"),value); \
}
// These keywords are used in the <1> command. The number is what you get if you use the keyword as a parameter.
// To discover new keyword numbers , use the <$ YOURKEYWORD> command
const int16_t HASH_KEYWORD_MAIN = 11339;
const int16_t HASH_KEYWORD_CABS = -11981;
const int16_t HASH_KEYWORD_RAM = 25982;
const int16_t HASH_KEYWORD_CMD = 9962;
const int16_t HASH_KEYWORD_ACK = 3113;
const int16_t HASH_KEYWORD_ON = 2657;
const int16_t HASH_KEYWORD_DCC = 6436;
const int16_t HASH_KEYWORD_SLOW = -17209;
#ifndef DISABLE_PROG
const int16_t HASH_KEYWORD_JOIN = -30750;
const int16_t HASH_KEYWORD_PROG = -29718;
const int16_t HASH_KEYWORD_PROGBOOST = -6353;
#endif
#ifndef DISABLE_EEPROM
const int16_t HASH_KEYWORD_EEPROM = -7168;
#endif
const int16_t HASH_KEYWORD_LIMIT = 27413;
const int16_t HASH_KEYWORD_MAX = 16244;
const int16_t HASH_KEYWORD_MIN = 15978;
const int16_t HASH_KEYWORD_RESET = 26133;
const int16_t HASH_KEYWORD_RETRY = 25704;
const int16_t HASH_KEYWORD_SPEED28 = -17064;
const int16_t HASH_KEYWORD_SPEED128 = 25816;
const int16_t HASH_KEYWORD_SERVO=27709;
const int16_t HASH_KEYWORD_TT=2688;
const int16_t HASH_KEYWORD_VPIN=-415;
const int16_t HASH_KEYWORD_A='A';
const int16_t HASH_KEYWORD_C='C';
const int16_t HASH_KEYWORD_G='G';
const int16_t HASH_KEYWORD_I='I';
const int16_t HASH_KEYWORD_R='R';
const int16_t HASH_KEYWORD_T='T';
const int16_t HASH_KEYWORD_X='X';
const int16_t HASH_KEYWORD_LCN = 15137;
const int16_t HASH_KEYWORD_HAL = 10853;
const int16_t HASH_KEYWORD_SHOW = -21309;
const int16_t HASH_KEYWORD_ANIN = -10424;
const int16_t HASH_KEYWORD_ANOUT = -26399;
const int16_t HASH_KEYWORD_WIFI = -5583;
const int16_t HASH_KEYWORD_ETHERNET = -30767;
const int16_t HASH_KEYWORD_WIT = 31594;
const int16_t HASH_KEYWORD_OTA = 22938;
int16_t DCCEXParser::stashP[MAX_COMMAND_PARAMS];
bool DCCEXParser::stashBusy;
Print *DCCEXParser::stashStream = NULL;
RingStream *DCCEXParser::stashRingStream = NULL;
byte DCCEXParser::stashTarget=0;
// This is a JMRI command parser.
// It doesnt know how the string got here, nor how it gets back.
// It knows nothing about hardware or tracks... it just parses strings and
// calls the corresponding DCC api.
// Non-DCC things like turnouts, pins and sensors are handled in additional JMRI interface classes.
int16_t DCCEXParser::splitValues(int16_t result[MAX_COMMAND_PARAMS], const byte *cmd, bool usehex)
{
byte state = 1;
byte parameterCount = 0;
int16_t runningValue = 0;
const byte *remainingCmd = cmd + 1; // skips the opcode
bool signNegative = false;
// clear all parameters in case not enough found
for (int16_t i = 0; i < MAX_COMMAND_PARAMS; i++)
result[i] = 0;
while (parameterCount < MAX_COMMAND_PARAMS)
{
byte hot = *remainingCmd;
switch (state)
{
case 1: // skipping spaces before a param
if (hot == ' ')
break;
if (hot == '\0' || hot == '>')
return parameterCount;
state = 2;
continue;
case 2: // checking sign
signNegative = false;
runningValue = 0;
state = 3;
if (hot != '-')
continue;
signNegative = true;
break;
case 3: // building a parameter
if (hot >= '0' && hot <= '9')
{
runningValue = (usehex?16:10) * runningValue + (hot - '0');
break;
}
if (hot >= 'a' && hot <= 'z') hot=hot-'a'+'A'; // uppercase a..z
if (usehex && hot>='A' && hot<='F') {
// treat A..F as hex not keyword
runningValue = 16 * runningValue + (hot - 'A' + 10);
break;
}
if (hot=='_' || (hot >= 'A' && hot <= 'Z'))
{
// Since JMRI got modified to send keywords in some rare cases, we need this
// Super Kluge to turn keywords into a hash value that can be recognised later
runningValue = ((runningValue << 5) + runningValue) ^ hot;
break;
}
result[parameterCount] = runningValue * (signNegative ? -1 : 1);
parameterCount++;
state = 1;
continue;
}
remainingCmd++;
}
return parameterCount;
}
extern __attribute__((weak)) void myFilter(Print * stream, byte & opcode, byte & paramCount, int16_t p[]);
FILTER_CALLBACK DCCEXParser::filterCallback = myFilter;
FILTER_CALLBACK DCCEXParser::filterRMFTCallback = 0;
AT_COMMAND_CALLBACK DCCEXParser::atCommandCallback = 0;
// deprecated
void DCCEXParser::setFilter(FILTER_CALLBACK filter)
{
filterCallback = filter;
}
void DCCEXParser::setRMFTFilter(FILTER_CALLBACK filter)
{
filterRMFTCallback = filter;
}
void DCCEXParser::setAtCommandCallback(AT_COMMAND_CALLBACK callback)
{
atCommandCallback = callback;
}
// Parse an F() string
void DCCEXParser::parse(const FSH * cmd) {
DIAG(F("SETUP(\"%S\")"),cmd);
int size=STRLEN_P((char *)cmd)+1;
char buffer[size];
STRCPY_P(buffer,(char *)cmd);
parse(&USB_SERIAL,(byte *)buffer,NULL);
}
// See documentation on DCC class for info on this section
void DCCEXParser::parse(Print *stream, byte *com, RingStream *ringStream) {
// This function can get stings of the form "<C OMM AND>" or "C OMM AND"
// found is true first after the leading "<" has been passed
bool found = (com[0] != '<');
for (byte *c=com; c[0] != '\0'; c++) {
if (found) {
parseOne(stream, c, ringStream);
found=false;
}
if (c[0] == '<')
found = true;
}
}
void DCCEXParser::parseOne(Print *stream, byte *com, RingStream * ringStream)
{
#ifdef DISABLE_PROG
(void)ringStream;
#endif
#ifndef DISABLE_EEPROM
(void)EEPROM; // tell compiler not to warn this is unused
#endif
if (Diag::CMD)
DIAG(F("PARSING:%s"), com);
int16_t p[MAX_COMMAND_PARAMS];
while (com[0] == '<' || com[0] == ' ')
com++; // strip off any number of < or spaces
byte opcode = com[0];
byte params = splitValues(p, com, opcode=='M' || opcode=='P');
if (filterCallback)
filterCallback(stream, opcode, params, p);
if (filterRMFTCallback && opcode!='\0')
filterRMFTCallback(stream, opcode, params, p);
// Functions return from this switch if complete, break from switch implies error <X> to send
switch (opcode)
{
case '\0':
return; // filterCallback asked us to ignore
case 't': // THROTTLE <t [REGISTER] CAB SPEED DIRECTION>
{
if (params==1) { // <t cab> display state
int16_t slot=DCC::lookupSpeedTable(p[0],false);
if (slot>=0) {
DCC::LOCO * sp=&DCC::speedTable[slot];
StringFormatter::send(stream,F("<l %d %d %d %l>\n"),
sp->loco,slot,sp->speedCode,sp->functions);
}
else // send dummy state speed 0 fwd no functions.
StringFormatter::send(stream,F("<l %d -1 128 0>\n"),p[0]);
return;
}
int16_t cab;
int16_t tspeed;
int16_t direction;
if (params == 4)
{ // <t REGISTER CAB SPEED DIRECTION>
cab = p[1];
tspeed = p[2];
direction = p[3];
}
else if (params == 3)
{ // <t CAB SPEED DIRECTION>
cab = p[0];
tspeed = p[1];
direction = p[2];
}
else
break;
// Convert DCC-EX protocol speed steps where
// -1=emergency stop, 0-126 as speeds
// to DCC 0=stop, 1= emergency stop, 2-127 speeds
if (tspeed > 126 || tspeed < -1)
break; // invalid JMRI speed code
if (tspeed < 0)
tspeed = 1; // emergency stop DCC speed
else if (tspeed > 0)
tspeed++; // map 1-126 -> 2-127
if (cab == 0 && tspeed > 1)
break; // ignore broadcasts of speed>1
if (direction < 0 || direction > 1)
break; // invalid direction code
if (cab > 10239 || cab < 0)
break; // beyond DCC range
DCC::setThrottle(cab, tspeed, direction);
if (params == 4) // send obsolete format T response
StringFormatter::send(stream, F("<T %d %d %d>\n"), p[0], p[2], p[3]);
// speed change will be broadcast anyway in new <l > format
return;
}
case 'f': // FUNCTION <f CAB BYTE1 [BYTE2]>
if (parsef(stream, params, p))
return;
break;
case 'a': // ACCESSORY <a ADDRESS SUBADDRESS ACTIVATE [ONOFF]> or <a LINEARADDRESS ACTIVATE>
{
int address;
byte subaddress;
byte activep;
byte onoff;
if (params==2) { // <a LINEARADDRESS ACTIVATE>
address=(p[0] - 1) / 4 + 1;
subaddress=(p[0] - 1) % 4;
activep=1;
onoff=2; // send both
}
else if (params==3) { // <a ADDRESS SUBADDRESS ACTIVATE>
address=p[0];
subaddress=p[1];
activep=2;
onoff=2; // send both
}
else if (params==4) { // <a ADDRESS SUBADDRESS ACTIVATE ONOFF>
address=p[0];
subaddress=p[1];
activep=2;
if ((p[3] < 0) || (p[3] > 1)) // invalid onoff 0|1
break;
onoff=p[3];
}
else break; // invalid no of parameters
if (
((address & 0x01FF) != address) // invalid address (limit 9 bits)
|| ((subaddress & 0x03) != subaddress) // invalid subaddress (limit 2 bits)
|| (p[activep] > 1) || (p[activep] < 0) // invalid activate 0|1
) break;
// Honour the configuration option (config.h) which allows the <a> command to be reversed
#ifdef DCC_ACCESSORY_COMMAND_REVERSE
DCC::setAccessory(address, subaddress,p[activep]==0,onoff);
#else
DCC::setAccessory(address, subaddress,p[activep]==1,onoff);
#endif
}
return;
case 'T': // TURNOUT <T ...>
if (parseT(stream, params, p))
return;
break;
case 'z': // direct pin manipulation
if (p[0]==0) break;
if (params==1) { // <z vpin | -vpin>
if (p[0]>0) IODevice::write(p[0],HIGH);
else IODevice::write(-p[0],LOW);
return;
}
if (params>=2 && params<=4) { // <z vpin ana;og profile duration>
// unused params default to 0
IODevice::writeAnalogue(p[0],p[1],p[2],p[3]);
return;
}
break;
case 'Z': // OUTPUT <Z ...>
if (parseZ(stream, params, p))
return;
break;
case 'S': // SENSOR <S ...>
if (parseS(stream, params, p))
return;
break;
#ifndef DISABLE_PROG
case 'w': // WRITE CV on MAIN <w CAB CV VALUE>
DCC::writeCVByteMain(p[0], p[1], p[2]);
return;
case 'b': // WRITE CV BIT ON MAIN <b CAB CV BIT VALUE>
DCC::writeCVBitMain(p[0], p[1], p[2], p[3]);
return;
#endif
case 'M': // WRITE TRANSPARENT DCC PACKET MAIN <M REG X1 ... X9>
#ifndef DISABLE_PROG
case 'P': // WRITE TRANSPARENT DCC PACKET PROG <P REG X1 ... X9>
#endif
// NOTE: this command was parsed in HEX instead of decimal
params--; // drop REG
if (params<1) break;
if (params > MAX_PACKET_SIZE) break;
{
byte packet[params];
for (int i=0;i<params;i++) {
packet[i]=(byte)p[i+1];
if (Diag::CMD) DIAG(F("packet[%d]=%d (0x%x)"), i, packet[i], packet[i]);
}
(opcode=='M'?DCCWaveform::mainTrack:DCCWaveform::progTrack).schedulePacket(packet,params,3);
}
return;
#ifndef DISABLE_PROG
case 'W': // WRITE CV ON PROG <W CV VALUE CALLBACKNUM CALLBACKSUB>
if (!stashCallback(stream, p, ringStream))
break;
if (params == 1) // <W id> Write new loco id (clearing consist and managing short/long)
DCC::setLocoId(p[0],callback_Wloco);
else if (params == 4) // WRITE CV ON PROG <W CV VALUE [CALLBACKNUM] [CALLBACKSUB]>
DCC::writeCVByte(p[0], p[1], callback_W4);
else // WRITE CV ON PROG <W CV VALUE>
DCC::writeCVByte(p[0], p[1], callback_W);
return;
case 'V': // VERIFY CV ON PROG <V CV VALUE> <V CV BIT 0|1>
if (params == 2)
{ // <V CV VALUE>
if (!stashCallback(stream, p, ringStream))
break;
DCC::verifyCVByte(p[0], p[1], callback_Vbyte);
return;
}
if (params == 3)
{
if (!stashCallback(stream, p, ringStream))
break;
DCC::verifyCVBit(p[0], p[1], p[2], callback_Vbit);
return;
}
break;
case 'B': // WRITE CV BIT ON PROG <B CV BIT VALUE CALLBACKNUM CALLBACKSUB>
if (!stashCallback(stream, p, ringStream))
break;
DCC::writeCVBit(p[0], p[1], p[2], callback_B);
return;
case 'R': // READ CV ON PROG
if (params == 1)
{ // <R CV> -- uses verify callback
if (!stashCallback(stream, p, ringStream))
break;
DCC::verifyCVByte(p[0], 0, callback_Vbyte);
return;
}
if (params == 3)
{ // <R CV CALLBACKNUM CALLBACKSUB>
if (!stashCallback(stream, p, ringStream))
break;
DCC::readCV(p[0], callback_R);
return;
}
if (params == 0)
{ // <R> New read loco id
if (!stashCallback(stream, p, ringStream))
break;
DCC::getLocoId(callback_Rloco);
return;
}
break;
#endif
case '1': // POWERON <1 [MAIN|PROG|JOIN]>
{
bool main=false;
bool prog=false;
bool join=false;
if (params > 1) break;
if (params==0) { // All
main=true;
prog=true;
}
if (params==1) {
if (p[0]==HASH_KEYWORD_MAIN) { // <1 MAIN>
main=true;
}
#ifndef DISABLE_PROG
else if (p[0] == HASH_KEYWORD_JOIN) { // <1 JOIN>
main=true;
prog=true;
join=true;
}
else if (p[0]==HASH_KEYWORD_PROG) { // <1 PROG>
prog=true;
}
#endif
else break; // will reply <X>
}
TrackManager::setJoin(join);
if (main) TrackManager::setMainPower(POWERMODE::ON);
if (prog) TrackManager::setProgPower(POWERMODE::ON);
CommandDistributor::broadcastPower();
return;
}
case '0': // POWEROFF <0 [MAIN | PROG] >
{
bool main=false;
bool prog=false;
if (params > 1) break;
if (params==0) { // All
main=true;
prog=true;
}
if (params==1) {
if (p[0]==HASH_KEYWORD_MAIN) { // <0 MAIN>
main=true;
}
#ifndef DISABLE_PROG
else if (p[0]==HASH_KEYWORD_PROG) { // <0 PROG>
prog=true;
}
#endif
else break; // will reply <X>
}
TrackManager::setJoin(false);
if (main) TrackManager::setMainPower(POWERMODE::OFF);
if (prog) {
TrackManager::progTrackBoosted=false; // Prog track boost mode will not outlive prog track off
TrackManager::setProgPower(POWERMODE::OFF);
}
CommandDistributor::broadcastPower();
return;
}
case '!': // ESTOP ALL <!>
DCC::setThrottle(0,1,1); // this broadcasts speed 1(estop) and sets all reminders to speed 1.
return;
case 'c': // SEND METER RESPONSES <c>
// No longer useful because of multiple tracks See <JG> and <JI>
if (params>0) break;
TrackManager::reportObsoleteCurrent(stream);
return;
case 'Q': // SENSORS <Q>
Sensor::printAll(stream);
return;
case 's': // <s>
StringFormatter::send(stream, F("<iDCC-EX V-%S / %S / %S G-%S>\n"), F(VERSION), F(ARDUINO_TYPE), DCC::getMotorShieldName(), F(GITHUB_SHA));
CommandDistributor::broadcastPower(); // <s> is the only "get power status" command we have
Turnout::printAll(stream); //send all Turnout states
Sensor::printAll(stream); //send all Sensor states
return;
#ifndef DISABLE_EEPROM
case 'E': // STORE EPROM <E>
EEStore::store();
StringFormatter::send(stream, F("<e %d %d %d>\n"), EEStore::eeStore->data.nTurnouts, EEStore::eeStore->data.nSensors, EEStore::eeStore->data.nOutputs);
return;
case 'e': // CLEAR EPROM <e>
EEStore::clear();
StringFormatter::send(stream, F("<O>\n"));
return;
#endif
case ' ': // < >
StringFormatter::send(stream, F("\n"));
return;
case 'D': // < >
if (parseD(stream, params, p))
return;
return;
case '=': // <= Track manager control >
if (TrackManager::parseJ(stream, params, p))
return;
break;
case '#': // NUMBER OF LOCOSLOTS <#>
StringFormatter::send(stream, F("<# %d>\n"), MAX_LOCOS);
return;
case '-': // Forget Loco <- [cab]>
if (params > 1 || p[0]<0) break;
if (p[0]==0) DCC::forgetAllLocos();
else DCC::forgetLoco(p[0]);
return;
case 'F': // New command to call the new Loco Function API <F cab func 1|0>
if(params!=3) break;
if (Diag::CMD)
DIAG(F("Setting loco %d F%d %S"), p[0], p[1], p[2] ? F("ON") : F("OFF"));
if (DCC::setFn(p[0], p[1], p[2] == 1)) return;
break;
#if WIFI_ON
case '+': // Complex Wifi interface command (not usual parse)
if (atCommandCallback && !ringStream) {
TrackManager::setPower(POWERMODE::OFF);
atCommandCallback((HardwareSerial *)stream,com);
return;
}
break;
#endif
case 'J' : // throttle info access
{
if ((params<1) | (params>3)) break; // <J>
//if ((params<1) | (params>2)) break; // <J>
int16_t id=(params==2)?p[1]:0;
switch(p[0]) {
case HASH_KEYWORD_C: // <JC mmmm nn> sets time and speed
if (params==1) { // <JC> returns latest time
int16_t x = CommandDistributor::retClockTime();
StringFormatter::send(stream, F("<jC %d>\n"), x);
return;
}
CommandDistributor::setClockTime(p[1], p[2], 1);
return;
case HASH_KEYWORD_G: // <JG> current gauge limits
if (params>1) break;
TrackManager::reportGauges(stream); // <g limit...limit>
return;
case HASH_KEYWORD_I: // <JI> current values
if (params>1) break;
TrackManager::reportCurrent(stream); // <g limit...limit>
return;
case HASH_KEYWORD_A: // <JA> returns automations/routes
StringFormatter::send(stream, F("<jA"));
if (params==1) {// <JA>
#ifdef EXRAIL_ACTIVE
SENDFLASHLIST(stream,RMFT2::routeIdList)
SENDFLASHLIST(stream,RMFT2::automationIdList)
#endif
}
else { // <JA id>
StringFormatter::send(stream,F(" %d %c \"%S\""),
id,
#ifdef EXRAIL_ACTIVE
RMFT2::getRouteType(id), // A/R
RMFT2::getRouteDescription(id)
#else
'X',F("")
#endif
);
}
StringFormatter::send(stream, F(">\n"));
return;
case HASH_KEYWORD_R: // <JR> returns rosters
StringFormatter::send(stream, F("<jR"));
#ifdef EXRAIL_ACTIVE
if (params==1) {
SENDFLASHLIST(stream,RMFT2::rosterIdList)
}
else {
auto rosterName= RMFT2::getRosterName(id);
if (!rosterName) rosterName=F("");
auto functionNames= RMFT2::getRosterFunctions(id);
if (!functionNames) functionNames=RMFT2::getRosterFunctions(0);
if (!functionNames) functionNames=F("");
StringFormatter::send(stream,F(" %d \"%S\" \"%S\""),
id, rosterName, functionNames);
}
#endif
StringFormatter::send(stream, F(">\n"));
return;
case HASH_KEYWORD_T: // <JT> returns turnout list
StringFormatter::send(stream, F("<jT"));
if (params==1) { // <JT>
for ( Turnout * t=Turnout::first(); t; t=t->next()) {
if (t->isHidden()) continue;
StringFormatter::send(stream, F(" %d"),t->getId());
}
}
else { // <JT id>
Turnout * t=Turnout::get(id);
if (!t || t->isHidden()) StringFormatter::send(stream, F(" %d X"),id);
else {
const FSH *tdesc = NULL;
#ifdef EXRAIL_ACTIVE
tdesc = RMFT2::getTurnoutDescription(id);
#endif
if (tdesc == NULL)
tdesc = F("");
StringFormatter::send(stream, F(" %d %c \"%S\""),
id,t->isThrown()?'T':'C',
tdesc);
}
}
StringFormatter::send(stream, F(">\n"));
return;
default: break;
} // switch(p[1])
break; // case J
}
default: //anything else will diagnose and drop out to <X>
DIAG(F("Opcode=%c params=%d"), opcode, params);
for (int i = 0; i < params; i++)
DIAG(F("p[%d]=%d (0x%x)"), i, p[i], p[i]);
break;
} // end of opcode switch
// Any fallout here sends an <X>
StringFormatter::send(stream, F("<X>\n"));
}
bool DCCEXParser::parseZ(Print *stream, int16_t params, int16_t p[])
{
switch (params)
{
case 2: // <Z ID ACTIVATE>
{
Output *o = Output::get(p[0]);
if (o == NULL)
return false;
o->activate(p[1]);
StringFormatter::send(stream, F("<Y %d %d>\n"), p[0], p[1]);
}
return true;
case 3: // <Z ID PIN IFLAG>
if (p[0] < 0 || p[2] < 0 || p[2] > 7 )
return false;
if (!Output::create(p[0], p[1], p[2], 1))
return false;
StringFormatter::send(stream, F("<O>\n"));
return true;
case 1: // <Z ID>
if (!Output::remove(p[0]))
return false;
StringFormatter::send(stream, F("<O>\n"));
return true;
case 0: // <Z> list Output definitions
{
bool gotone = false;
for (Output *tt = Output::firstOutput; tt != NULL; tt = tt->nextOutput)
{
gotone = true;
StringFormatter::send(stream, F("<Y %d %d %d %d>\n"), tt->data.id, tt->data.pin, tt->data.flags, tt->data.active);
}
return gotone;
}
default:
return false;
}
}
//===================================
bool DCCEXParser::parsef(Print *stream, int16_t params, int16_t p[])
{
// JMRI sends this info in DCC message format but it's not exactly
// convenient for other processing
if (params == 2) {
byte instructionField = p[1] & 0xE0; // 1110 0000
if (instructionField == 0x80) { // 1000 0000 Function group 1
// Shuffle bits from order F0 F4 F3 F2 F1 to F4 F3 F2 F1 F0
byte normalized = (p[1] << 1 & 0x1e) | (p[1] >> 4 & 0x01);
return (funcmap(p[0], normalized, 0, 4));
} else if (instructionField == 0xA0) { // 1010 0000 Function group 2
if (p[1] & 0x10) // 0001 0000 Bit selects F5toF8 / F9toF12
return (funcmap(p[0], p[1], 5, 8));
else
return (funcmap(p[0], p[1], 9, 12));
}
}
if (params == 3) {
if (p[1] == 222) {
return (funcmap(p[0], p[2], 13, 20));
} else if (p[1] == 223) {
return (funcmap(p[0], p[2], 21, 28));
}
}
(void)stream; // NO RESPONSE
return false;
}
bool DCCEXParser::funcmap(int16_t cab, byte value, byte fstart, byte fstop)
{
for (int16_t i = fstart; i <= fstop; i++) {
if (! DCC::setFn(cab, i, value & 1)) return false;
value >>= 1;
}
return true;
}
//===================================
bool DCCEXParser::parseT(Print *stream, int16_t params, int16_t p[])
{
switch (params)
{
case 0: // <T> list turnout definitions
return Turnout::printAll(stream); // will <X> if none found
case 1: // <T id> delete turnout
if (!Turnout::remove(p[0]))
return false;
StringFormatter::send(stream, F("<O>\n"));
return true;
case 2: // <T id 0|1|T|C>
{
bool state = false;
switch (p[1]) {
// Turnout messages use 1=throw, 0=close.
case 0:
case HASH_KEYWORD_C:
state = true;
break;
case 1:
case HASH_KEYWORD_T:
state= false;
break;
case HASH_KEYWORD_X:
{
Turnout *tt = Turnout::get(p[0]);
if (tt) {
tt->print(stream);
return true;
}
return false;
}
default: // Invalid parameter
return false;
}
if (!Turnout::setClosed(p[0], state)) return false;
return true;
}
default: // Anything else is some kind of turnout create function.
if (params == 6 && p[1] == HASH_KEYWORD_SERVO) { // <T id SERVO n n n n>
if (!ServoTurnout::create(p[0], (VPIN)p[2], (uint16_t)p[3], (uint16_t)p[4], (uint8_t)p[5]))
return false;
} else
if (params == 3 && p[1] == HASH_KEYWORD_VPIN) { // <T id VPIN n>
if (!VpinTurnout::create(p[0], p[2])) return false;
} else
if (params >= 3 && p[1] == HASH_KEYWORD_DCC) {
// <T id DCC addr subadd> 0<=addr<=511, 0<=subadd<=3 (like <a> command).<T>
if (params==4 && p[2]>=0 && p[2]<512 && p[3]>=0 && p[3]<4) { // <T id DCC n m>
if (!DCCTurnout::create(p[0], p[2], p[3])) return false;
} else if (params==3 && p[2]>0 && p[2]<=512*4) { // <T id DCC nn>, 1<=nn<=2048
// Linearaddress 1 maps onto decoder address 1/0 (not 0/0!).
if (!DCCTurnout::create(p[0], (p[2]-1)/4+1, (p[2]-1)%4)) return false;
} else
return false;
} else
if (params==3) { // legacy <T id addr subadd> for DCC accessory
if (p[1]>=0 && p[1]<512 && p[2]>=0 && p[2]<4) {
if (!DCCTurnout::create(p[0], p[1], p[2])) return false;
} else
return false;
}
else
if (params==4) { // legacy <T id n n n> for Servo
if (!ServoTurnout::create(p[0], (VPIN)p[1], (uint16_t)p[2], (uint16_t)p[3], 1)) return false;
} else
return false;
StringFormatter::send(stream, F("<O>\n"));
return true;
}
}
bool DCCEXParser::parseS(Print *stream, int16_t params, int16_t p[])
{
switch (params)
{
case 3: // <S id pin pullup> create sensor. pullUp indicator (0=LOW/1=HIGH)
if (!Sensor::create(p[0], p[1], p[2]))
return false;
StringFormatter::send(stream, F("<O>\n"));
return true;
case 1: // S id> remove sensor
if (!Sensor::remove(p[0]))
return false;
StringFormatter::send(stream, F("<O>\n"));
return true;
case 0: // <S> list sensor definitions
if (Sensor::firstSensor == NULL)
return false;
for (Sensor *tt = Sensor::firstSensor; tt != NULL; tt = tt->nextSensor)
{
StringFormatter::send(stream, F("<Q %d %d %d>\n"), tt->data.snum, tt->data.pin, tt->data.pullUp);
}
return true;
default: // invalid number of arguments
break;
}
return false;
}
bool DCCEXParser::parseD(Print *stream, int16_t params, int16_t p[])
{
if (params == 0)
return false;
bool onOff = (params > 0) && (p[1] == 1 || p[1] == HASH_KEYWORD_ON); // dont care if other stuff or missing... just means off
switch (p[0])
{
case HASH_KEYWORD_CABS: // <D CABS>
DCC::displayCabList(stream);
return true;
case HASH_KEYWORD_RAM: // <D RAM>
StringFormatter::send(stream, F("Free memory=%d\n"), DCCTimer::getMinimumFreeMemory());
return true;
#ifndef DISABLE_PROG
case HASH_KEYWORD_ACK: // <D ACK ON/OFF> <D ACK [LIMIT|MIN|MAX|RETRY] Value>
if (params >= 3) {
if (p[1] == HASH_KEYWORD_LIMIT) {
DCCACK::setAckLimit(p[2]);
LCD(1, F("Ack Limit=%dmA"), p[2]); // <D ACK LIMIT 42>
} else if (p[1] == HASH_KEYWORD_MIN) {
DCCACK::setMinAckPulseDuration(p[2]);
LCD(0, F("Ack Min=%uus"), p[2]); // <D ACK MIN 1500>
} else if (p[1] == HASH_KEYWORD_MAX) {
DCCACK::setMaxAckPulseDuration(p[2]);
LCD(0, F("Ack Max=%uus"), p[2]); // <D ACK MAX 9000>
} else if (p[1] == HASH_KEYWORD_RETRY) {
if (p[2] >255) p[2]=3;
LCD(0, F("Ack Retry=%d Sum=%d"), p[2], DCCACK::setAckRetry(p[2])); // <D ACK RETRY 2>
}
} else {
StringFormatter::send(stream, F("Ack diag %S\n"), onOff ? F("on") : F("off"));
Diag::ACK = onOff;
}
return true;
#endif
case HASH_KEYWORD_CMD: // <D CMD ON/OFF>
Diag::CMD = onOff;
return true;
#ifdef HAS_ENOUGH_MEMORY
case HASH_KEYWORD_WIFI: // <D WIFI ON/OFF>
Diag::WIFI = onOff;
return true;
case HASH_KEYWORD_ETHERNET: // <D ETHERNET ON/OFF>
Diag::ETHERNET = onOff;
return true;
case HASH_KEYWORD_WIT: // <D WIT ON/OFF>
Diag::WITHROTTLE = onOff;
return true;
case HASH_KEYWORD_LCN: // <D LCN ON/OFF>
Diag::LCN = onOff;
return true;
#endif
#ifndef DISABLE_PROG
case HASH_KEYWORD_PROGBOOST:
TrackManager::progTrackBoosted=true;
return true;
#endif
case HASH_KEYWORD_RESET:
DCCTimer::reset();
break; // and <X> if we didnt restart
#ifndef DISABLE_EEPROM
case HASH_KEYWORD_EEPROM: // <D EEPROM NumEntries>
if (params >= 2)
EEStore::dump(p[1]);
return true;
#endif
case HASH_KEYWORD_SPEED28:
DCC::setGlobalSpeedsteps(28);
StringFormatter::send(stream, F("28 Speedsteps"));
return true;
case HASH_KEYWORD_SPEED128:
DCC::setGlobalSpeedsteps(128);
StringFormatter::send(stream, F("128 Speedsteps"));
return true;
case HASH_KEYWORD_SERVO: // <D SERVO vpin position [profile]>
case HASH_KEYWORD_ANOUT: // <D ANOUT vpin position [profile]>
IODevice::writeAnalogue(p[1], p[2], params>3 ? p[3] : 0);
break;
case HASH_KEYWORD_ANIN: // <D ANIN vpin> Display analogue input value
DIAG(F("VPIN=%u value=%d"), p[1], IODevice::readAnalogue(p[1]));
break;
#if !defined(IO_NO_HAL)
case HASH_KEYWORD_HAL:
if (p[1] == HASH_KEYWORD_SHOW)
IODevice::DumpAll();
else if (p[1] == HASH_KEYWORD_RESET)
IODevice::reset();
break;
#endif
case HASH_KEYWORD_TT: // <D TT vpin steps activity>
IODevice::writeAnalogue(p[1], p[2], params>3 ? p[3] : 0);
break;
case HASH_KEYWORD_OTA: // <D OTA ON/OFF>
Diag::OTA = onOff;
DIAG(F("OTA=%S"), onOff ? F("ON") : F("OFF"));
return true;
default: // invalid/unknown
break;
}
return false;
}
// CALLBACKS must be static
bool DCCEXParser::stashCallback(Print *stream, int16_t p[MAX_COMMAND_PARAMS], RingStream * ringStream)
{
if (stashBusy )
return false;
stashBusy = true;
stashStream = stream;
stashRingStream=ringStream;
if (ringStream) stashTarget= ringStream->peekTargetMark();
memcpy(stashP, p, MAX_COMMAND_PARAMS * sizeof(p[0]));
return true;
}
Print * DCCEXParser::getAsyncReplyStream() {
if (stashRingStream) {
stashRingStream->mark(stashTarget);
return stashRingStream;
}
return stashStream;
}
void DCCEXParser::commitAsyncReplyStream() {
if (stashRingStream) stashRingStream->commit();
stashBusy = false;
}
void DCCEXParser::callback_W(int16_t result)
{
StringFormatter::send(getAsyncReplyStream(),
F("<r %d %d>\n"), stashP[0], result == 1 ? stashP[1] : -1);
commitAsyncReplyStream();
}
void DCCEXParser::callback_W4(int16_t result)
{
StringFormatter::send(getAsyncReplyStream(),
F("<r%d|%d|%d %d>\n"), stashP[2], stashP[3], stashP[0], result == 1 ? stashP[1] : -1);
commitAsyncReplyStream();
}
void DCCEXParser::callback_B(int16_t result)
{
StringFormatter::send(getAsyncReplyStream(),
F("<r%d|%d|%d %d %d>\n"), stashP[3], stashP[4], stashP[0], stashP[1], result == 1 ? stashP[2] : -1);
commitAsyncReplyStream();
}
void DCCEXParser::callback_Vbit(int16_t result)
{
StringFormatter::send(getAsyncReplyStream(), F("<v %d %d %d>\n"), stashP[0], stashP[1], result);
commitAsyncReplyStream();
}
void DCCEXParser::callback_Vbyte(int16_t result)
{
StringFormatter::send(getAsyncReplyStream(), F("<v %d %d>\n"), stashP[0], result);
commitAsyncReplyStream();
}
void DCCEXParser::callback_R(int16_t result)
{
StringFormatter::send(getAsyncReplyStream(), F("<r%d|%d|%d %d>\n"), stashP[1], stashP[2], stashP[0], result);
commitAsyncReplyStream();
}
void DCCEXParser::callback_Rloco(int16_t result) {
const FSH * detail;
if (result<=0) {
detail=F("<r %d>\n");
} else {
bool longAddr=result & LONG_ADDR_MARKER; //long addr
if (longAddr)
result = result^LONG_ADDR_MARKER;
if (longAddr && result <= HIGHEST_SHORT_ADDR)
detail=F("<r LONG %d UNSUPPORTED>\n");
else
detail=F("<r %d>\n");
}
StringFormatter::send(getAsyncReplyStream(), detail, result);
commitAsyncReplyStream();
}
void DCCEXParser::callback_Wloco(int16_t result)
{
if (result==1) result=stashP[0]; // pick up original requested id from command
StringFormatter::send(getAsyncReplyStream(), F("<w %d>\n"), result);
commitAsyncReplyStream();
}